Universal framework for the long-time position distribution of free active particles

Santra, Ion; Basu, Urna; Sabhapandit, Sanjib

doi:10.1088/1751-8121/ac864c

“…The exponentially decaying autocorrelation is a hallmark of active particle motion [62,63]. Popular models like run-and-tumble particles [64][65][66] and active Ornstein-Uhlenbeck particles [67] exhibit exponentially decaying correlation of the propulsion velocity at all times.…”

Section: Modelmentioning

confidence: 99%

Dynamical fluctuations of a tracer coupled to active and passive particles

Santra

¹

2023

Self Cite

View full text Add to dashboard Cite

We study the induced dynamics of an inertial tracer particle elastically coupled to passive or active Brownian particles. We integrate out the environment degrees of freedom to obtain generalized Langevin equation for the tracer dynamics in both cases. In particular, we ﬁnd the exact form of the dissipation kernel and eﬀective noise experienced by the tracer and compare it with the phenomenological modeling of active baths used in previous studies. We show that the second ﬂuctuation-dissipation relation (FDR) does not hold at early times for both cases. However, at ﬁnite times, the tracer dynamics violate (obeys) the FDR for the active (passive) environment. We calculate the linear response formulas in this regime for both cases and show that the passive medium satisﬁes an equilibrium ﬂuctuation response relation (FRR), while the active medium does not—we quantify the extent of this violation explicitly. We show that though the active medium generally renders a nonequilibrium description of the tracer, an eﬀective equilibrium picture emerges asymptotically in the small activity limit of the medium. We also calculate the mean squared velocity and mean squared displacement of the tracer and report how they vary with time.

show abstract

“…In the following, we solve the above equation perturbatively, by treating ε 2 /t as a small parameter following the framework developed recently [43]. To explicitly obtain the coefficient of the (ε 2 /t) k term in the perturbative series, the knowledge of the position moments ⟨y 2k (t)⟩ is required.…”

Section: J Stat Mech (2023) 033203mentioning

confidence: 99%

“…Proceeding similarly, one can systematically calculate the higher order corrections. Finally, remembering that the isotropy of two-dimensional position distribution, the radial distribution of the RTP in the diffusive scaling limit can be expressed in the universal form [43],…”

Section: J Stat Mech (2023) 033203mentioning

confidence: 99%

“…In fact, there is no general formalism to understand these active dynamics, and one has to approach the different models of self-propulsion in different ways to extract their statistical properties. Recently, however, it was shown [43] that the long-time dynamics of active particles show certain universal behavior irrespective of the specific dynamics of the stochastic propulsion velocity, namely, the leading order position distribution is a Gaussian with a diffusive scaling and the subleading corrections to this leading order Gaussian follow an inhomogeneous diffusion equation. The specificity of the different active dynamics enters through the source term only, which, at each order, depends on the previous order solutions.…”

Section: Introductionmentioning

confidence: 99%

“…To understand the effects of the activity of an RTP at late times via the large deviation functions experimentally is challenging as the O(t) events are rare. In this paper, we study the O( √ t) fluctuations beyond Gaussian, of the two-dimensional RTP at long-times using the formalism developed in [43]. Starting from the Fokker-Planck equation, we show that at the leading order, the position distribution satisfies a diffusion equation, which yields a leading order Gaussian position distribution.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Long time behavior of run-and-tumble particles in two dimensions

Santra¹,

Basu²,

Sabhapandit³

2023

J. Stat. Mech.

Self Cite

0

View full text Add to dashboard Cite

We study the long-time asymptotic behavior of the position distribution of a run-and-tumble particle (RTP) in two dimensions in the presence of translational diffusion and show that the distribution at a time t can be expressed as a perturbative series in ( γ t ) − 1 , where γ −1 is the persistence time of the RTP. We show that the higher order corrections to the leading order Gaussian distribution generically satisfy an inhomogeneous diffusion equation where the source term depends on the previous order solutions. The explicit solution of the inhomogeneous equation requires the position moments, and we develop a recursive formalism to compute the same. We find that the subleading corrections undergo shape transitions as the translational diffusion is increased.

show abstract

Chirality reversing active Brownian motion in two dimensions

Das¹,

Basu²

2023

J. Stat. Mech.

Self Cite

0

View full text Add to dashboard Cite

We study the dynamics of a chirality reversing active Brownian particle (ABP), which models the chirality reversing active motion common in many microorganisms and microswimmers. We show that, for such a motion, the presence of the two time-scales set by the chirality reversing rate γ and rotational diffusion constant D R gives rise to four dynamical regimes, namely, (I) t ≪ min ( γ − 1 , D R − 1 ) , (II) γ − 1 ≪ t ≪ D R − 1 , (III) D R − 1 ≪ t ≪ γ − 1 and (IV) t ≫ max ( γ − 1 , D R − 1 ) , each showing different behavior. The short-time regime (I) is characterized by a strongly anisotropic and non-Gaussian position distribution, which crosses over to a diffusive Gaussian behavior in the long-time regime (IV) via an intermediate regime (II) or (III), depending on the relative strength of γ and D R . In regime (II), the chirality reversing active Brownian motion reduces to that of an ordinary ABP, with an effective rotation diffusion coefficient which depends on the angular velocity. Finally, we find that, the regime (III) is characterized by an effective chiral active Brownian motion.

show abstract

Universal framework for the long-time position distribution of free active particles

Cited by 8 publications

References 48 publications

Dynamical fluctuations of a tracer coupled to active and passive particles

Dynamical fluctuations of a tracer coupled to active and passive particles

Long time behavior of run-and-tumble particles in two dimensions

Chirality reversing active Brownian motion in two dimensions

Contact Info

Product

Resources

About